Giant Pressure-Driven Lattice Collapse Coupled with Intermetallic Bonding and Spin-State Transition in Manganese Chalcogenides
Document Type
Article
Publication Date
1-1-2016
Publication Title
Angewandte Chemie - International Edition
Volume
55
Issue
35
First page number:
10350
Last page number:
10353
Abstract
Materials with an abrupt volume collapse of more than 20 % during a pressure-induced phase transition are rarely reported. In such an intriguing phenomenon, the lattice may be coupled with dramatic changes of orbital and/or the spin-state of the transition metal. A combined in situ crystallography and electron spin-state study to probe the mechanism of the pressure-driven lattice collapse in MnS and MnSe is presented. Both materials exhibit a rocksalt-to-MnP phase transition under compression with ca. 22 % unit-cell volume changes, which was found to be coupled with the Mn2+(d5) spin-state transition from S=5/2 to S=1/2 and the formation of Mn−Mn intermetallic bonds as supported by the metallic transport behavior of their high-pressure phases. Our results reveal the mutual relationship between pressure-driven lattice collapse and the orbital/spin-state of Mn2+in manganese chalcogenides and also provide deeper insights toward the exploration of new metastable phases with exceptional functionalities. © 2016 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim
Keywords
high pressure; intermetallic bonding; lattice collapse; manganese chalcogenides; spin-state transitions
File Format
File Size
1370 KB
Language
English
Repository Citation
Wang, Y.,
Bai, L.,
Wen, T.,
Yang, L.,
Gou, H.,
Xiao, Y.,
Chow, P.,
Pravica, M.,
Yang, W.,
Zhao, Y.
(2016).
Giant Pressure-Driven Lattice Collapse Coupled with Intermetallic Bonding and Spin-State Transition in Manganese Chalcogenides.
Angewandte Chemie - International Edition, 55(35),
10350-10353.
http://dx.doi.org/10.1002/anie.201605410